rust/src/libstd/serialize.rs

578 lines
14 KiB
Rust

// Copyright 2012 The Rust Project Developers. See the COPYRIGHT
// file at the top-level directory of this distribution and at
// http://rust-lang.org/COPYRIGHT.
//
// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
// option. This file may not be copied, modified, or distributed
// except according to those terms.
//! Support code for encoding and decoding types.
/*
Core encoding and decoding interfaces.
*/
#[forbid(non_camel_case_types)];
use core::at_vec;
use core::prelude::*;
use core::vec;
pub trait Encoder {
// Primitive types:
fn emit_nil(&self);
fn emit_uint(&self, v: uint);
fn emit_u64(&self, v: u64);
fn emit_u32(&self, v: u32);
fn emit_u16(&self, v: u16);
fn emit_u8(&self, v: u8);
fn emit_int(&self, v: int);
fn emit_i64(&self, v: i64);
fn emit_i32(&self, v: i32);
fn emit_i16(&self, v: i16);
fn emit_i8(&self, v: i8);
fn emit_bool(&self, v: bool);
fn emit_float(&self, v: float);
fn emit_f64(&self, v: f64);
fn emit_f32(&self, v: f32);
fn emit_char(&self, v: char);
fn emit_borrowed_str(&self, v: &str);
fn emit_owned_str(&self, v: &str);
fn emit_managed_str(&self, v: &str);
// Compound types:
fn emit_borrowed(&self, f: &fn());
fn emit_owned(&self, f: &fn());
fn emit_managed(&self, f: &fn());
fn emit_enum(&self, name: &str, f: &fn());
fn emit_enum_variant(&self, v_name: &str, v_id: uint, sz: uint, f: &fn());
fn emit_enum_variant_arg(&self, idx: uint, f: &fn());
fn emit_borrowed_vec(&self, len: uint, f: &fn());
fn emit_owned_vec(&self, len: uint, f: &fn());
fn emit_managed_vec(&self, len: uint, f: &fn());
fn emit_vec_elt(&self, idx: uint, f: &fn());
fn emit_rec(&self, f: &fn());
fn emit_struct(&self, name: &str, _len: uint, f: &fn());
fn emit_field(&self, f_name: &str, f_idx: uint, f: &fn());
fn emit_tup(&self, len: uint, f: &fn());
fn emit_tup_elt(&self, idx: uint, f: &fn());
}
pub trait Decoder {
// Primitive types:
fn read_nil(&self) -> ();
fn read_uint(&self) -> uint;
fn read_u64(&self) -> u64;
fn read_u32(&self) -> u32;
fn read_u16(&self) -> u16;
fn read_u8(&self) -> u8;
fn read_int(&self) -> int;
fn read_i64(&self) -> i64;
fn read_i32(&self) -> i32;
fn read_i16(&self) -> i16;
fn read_i8(&self) -> i8;
fn read_bool(&self) -> bool;
fn read_f64(&self) -> f64;
fn read_f32(&self) -> f32;
fn read_float(&self) -> float;
fn read_char(&self) -> char;
fn read_owned_str(&self) -> ~str;
fn read_managed_str(&self) -> @str;
// Compound types:
fn read_enum<T>(&self, name: &str, f: &fn() -> T) -> T;
fn read_enum_variant<T>(&self, f: &fn(uint) -> T) -> T;
fn read_enum_variant_arg<T>(&self, idx: uint, f: &fn() -> T) -> T;
fn read_owned<T>(&self, f: &fn() -> T) -> T;
fn read_managed<T>(&self, f: &fn() -> T) -> T;
fn read_owned_vec<T>(&self, f: &fn(uint) -> T) -> T;
fn read_managed_vec<T>(&self, f: &fn(uint) -> T) -> T;
fn read_vec_elt<T>(&self, idx: uint, f: &fn() -> T) -> T;
fn read_rec<T>(&self, f: &fn() -> T) -> T;
fn read_struct<T>(&self, name: &str, _len: uint, f: &fn() -> T) -> T;
fn read_field<T>(&self, name: &str, idx: uint, f: &fn() -> T) -> T;
fn read_tup<T>(&self, sz: uint, f: &fn() -> T) -> T;
fn read_tup_elt<T>(&self, idx: uint, f: &fn() -> T) -> T;
}
pub trait Encodable<S:Encoder> {
fn encode(&self, s: &S);
}
pub trait Decodable<D:Decoder> {
fn decode(d: &D) -> Self;
}
impl<S:Encoder> Encodable<S> for uint {
fn encode(&self, s: &S) { s.emit_uint(*self) }
}
impl<D:Decoder> Decodable<D> for uint {
fn decode(d: &D) -> uint {
d.read_uint()
}
}
impl<S:Encoder> Encodable<S> for u8 {
fn encode(&self, s: &S) { s.emit_u8(*self) }
}
impl<D:Decoder> Decodable<D> for u8 {
fn decode(d: &D) -> u8 {
d.read_u8()
}
}
impl<S:Encoder> Encodable<S> for u16 {
fn encode(&self, s: &S) { s.emit_u16(*self) }
}
impl<D:Decoder> Decodable<D> for u16 {
fn decode(d: &D) -> u16 {
d.read_u16()
}
}
impl<S:Encoder> Encodable<S> for u32 {
fn encode(&self, s: &S) { s.emit_u32(*self) }
}
impl<D:Decoder> Decodable<D> for u32 {
fn decode(d: &D) -> u32 {
d.read_u32()
}
}
impl<S:Encoder> Encodable<S> for u64 {
fn encode(&self, s: &S) { s.emit_u64(*self) }
}
impl<D:Decoder> Decodable<D> for u64 {
fn decode(d: &D) -> u64 {
d.read_u64()
}
}
impl<S:Encoder> Encodable<S> for int {
fn encode(&self, s: &S) { s.emit_int(*self) }
}
impl<D:Decoder> Decodable<D> for int {
fn decode(d: &D) -> int {
d.read_int()
}
}
impl<S:Encoder> Encodable<S> for i8 {
fn encode(&self, s: &S) { s.emit_i8(*self) }
}
impl<D:Decoder> Decodable<D> for i8 {
fn decode(d: &D) -> i8 {
d.read_i8()
}
}
impl<S:Encoder> Encodable<S> for i16 {
fn encode(&self, s: &S) { s.emit_i16(*self) }
}
impl<D:Decoder> Decodable<D> for i16 {
fn decode(d: &D) -> i16 {
d.read_i16()
}
}
impl<S:Encoder> Encodable<S> for i32 {
fn encode(&self, s: &S) { s.emit_i32(*self) }
}
impl<D:Decoder> Decodable<D> for i32 {
fn decode(d: &D) -> i32 {
d.read_i32()
}
}
impl<S:Encoder> Encodable<S> for i64 {
fn encode(&self, s: &S) { s.emit_i64(*self) }
}
impl<D:Decoder> Decodable<D> for i64 {
fn decode(d: &D) -> i64 {
d.read_i64()
}
}
impl<S:Encoder> Encodable<S> for &'self str {
fn encode(&self, s: &S) { s.emit_borrowed_str(*self) }
}
impl<S:Encoder> Encodable<S> for ~str {
fn encode(&self, s: &S) { s.emit_owned_str(*self) }
}
impl<D:Decoder> Decodable<D> for ~str {
fn decode(d: &D) -> ~str {
d.read_owned_str()
}
}
impl<S:Encoder> Encodable<S> for @str {
fn encode(&self, s: &S) { s.emit_managed_str(*self) }
}
impl<D:Decoder> Decodable<D> for @str {
fn decode(d: &D) -> @str {
d.read_managed_str()
}
}
impl<S:Encoder> Encodable<S> for float {
fn encode(&self, s: &S) { s.emit_float(*self) }
}
impl<D:Decoder> Decodable<D> for float {
fn decode(d: &D) -> float {
d.read_float()
}
}
impl<S:Encoder> Encodable<S> for f32 {
fn encode(&self, s: &S) { s.emit_f32(*self) }
}
impl<D:Decoder> Decodable<D> for f32 {
fn decode(d: &D) -> f32 {
d.read_f32() }
}
impl<S:Encoder> Encodable<S> for f64 {
fn encode(&self, s: &S) { s.emit_f64(*self) }
}
impl<D:Decoder> Decodable<D> for f64 {
fn decode(d: &D) -> f64 {
d.read_f64()
}
}
impl<S:Encoder> Encodable<S> for bool {
fn encode(&self, s: &S) { s.emit_bool(*self) }
}
impl<D:Decoder> Decodable<D> for bool {
fn decode(d: &D) -> bool {
d.read_bool()
}
}
impl<S:Encoder> Encodable<S> for () {
fn encode(&self, s: &S) { s.emit_nil() }
}
impl<D:Decoder> Decodable<D> for () {
fn decode(d: &D) -> () {
d.read_nil()
}
}
impl<S:Encoder,T:Encodable<S>> Encodable<S> for &'self T {
fn encode(&self, s: &S) {
s.emit_borrowed(|| (**self).encode(s))
}
}
impl<S:Encoder,T:Encodable<S>> Encodable<S> for ~T {
fn encode(&self, s: &S) {
s.emit_owned(|| (**self).encode(s))
}
}
impl<D:Decoder,T:Decodable<D>> Decodable<D> for ~T {
fn decode(d: &D) -> ~T {
d.read_owned(|| ~Decodable::decode(d))
}
}
impl<S:Encoder,T:Encodable<S>> Encodable<S> for @T {
fn encode(&self, s: &S) {
s.emit_managed(|| (**self).encode(s))
}
}
impl<D:Decoder,T:Decodable<D>> Decodable<D> for @T {
fn decode(d: &D) -> @T {
d.read_managed(|| @Decodable::decode(d))
}
}
impl<S:Encoder,T:Encodable<S>> Encodable<S> for &'self [T] {
fn encode(&self, s: &S) {
do s.emit_borrowed_vec(self.len()) {
for self.eachi |i, e| {
s.emit_vec_elt(i, || e.encode(s))
}
}
}
}
impl<S:Encoder,T:Encodable<S>> Encodable<S> for ~[T] {
fn encode(&self, s: &S) {
do s.emit_owned_vec(self.len()) {
for self.eachi |i, e| {
s.emit_vec_elt(i, || e.encode(s))
}
}
}
}
impl<D:Decoder,T:Decodable<D>> Decodable<D> for ~[T] {
fn decode(d: &D) -> ~[T] {
do d.read_owned_vec |len| {
do vec::from_fn(len) |i| {
d.read_vec_elt(i, || Decodable::decode(d))
}
}
}
}
impl<S:Encoder,T:Encodable<S>> Encodable<S> for @[T] {
fn encode(&self, s: &S) {
do s.emit_managed_vec(self.len()) {
for self.eachi |i, e| {
s.emit_vec_elt(i, || e.encode(s))
}
}
}
}
impl<D:Decoder,T:Decodable<D>> Decodable<D> for @[T] {
fn decode(d: &D) -> @[T] {
do d.read_managed_vec |len| {
do at_vec::from_fn(len) |i| {
d.read_vec_elt(i, || Decodable::decode(d))
}
}
}
}
impl<S:Encoder,T:Encodable<S>> Encodable<S> for Option<T> {
fn encode(&self, s: &S) {
do s.emit_enum(~"option") {
match *self {
None => do s.emit_enum_variant(~"none", 0u, 0u) {
},
Some(ref v) => do s.emit_enum_variant(~"some", 1u, 1u) {
s.emit_enum_variant_arg(0u, || v.encode(s))
}
}
}
}
}
impl<D:Decoder,T:Decodable<D>> Decodable<D> for Option<T> {
fn decode(d: &D) -> Option<T> {
do d.read_enum(~"option") {
do d.read_enum_variant |i| {
match i {
0 => None,
1 => Some(d.read_enum_variant_arg(
0u, || Decodable::decode(d))),
_ => fail!(fmt!("Bad variant for option: %u", i))
}
}
}
}
}
impl<S:Encoder,T0:Encodable<S>,T1:Encodable<S>> Encodable<S> for (T0, T1) {
fn encode(&self, s: &S) {
match *self {
(ref t0, ref t1) => {
do s.emit_tup(2) {
s.emit_tup_elt(0, || t0.encode(s));
s.emit_tup_elt(1, || t1.encode(s));
}
}
}
}
}
impl<D:Decoder,T0:Decodable<D>,T1:Decodable<D>> Decodable<D> for (T0, T1) {
fn decode(d: &D) -> (T0, T1) {
do d.read_tup(2) {
(
d.read_tup_elt(0, || Decodable::decode(d)),
d.read_tup_elt(1, || Decodable::decode(d))
)
}
}
}
impl<
S: Encoder,
T0: Encodable<S>,
T1: Encodable<S>,
T2: Encodable<S>
> Encodable<S> for (T0, T1, T2) {
fn encode(&self, s: &S) {
match *self {
(ref t0, ref t1, ref t2) => {
do s.emit_tup(3) {
s.emit_tup_elt(0, || t0.encode(s));
s.emit_tup_elt(1, || t1.encode(s));
s.emit_tup_elt(2, || t2.encode(s));
}
}
}
}
}
impl<
D: Decoder,
T0: Decodable<D>,
T1: Decodable<D>,
T2: Decodable<D>
> Decodable<D> for (T0, T1, T2) {
fn decode(d: &D) -> (T0, T1, T2) {
do d.read_tup(3) {
(
d.read_tup_elt(0, || Decodable::decode(d)),
d.read_tup_elt(1, || Decodable::decode(d)),
d.read_tup_elt(2, || Decodable::decode(d))
)
}
}
}
impl<
S: Encoder,
T0: Encodable<S>,
T1: Encodable<S>,
T2: Encodable<S>,
T3: Encodable<S>
> Encodable<S> for (T0, T1, T2, T3) {
fn encode(&self, s: &S) {
match *self {
(ref t0, ref t1, ref t2, ref t3) => {
do s.emit_tup(4) {
s.emit_tup_elt(0, || t0.encode(s));
s.emit_tup_elt(1, || t1.encode(s));
s.emit_tup_elt(2, || t2.encode(s));
s.emit_tup_elt(3, || t3.encode(s));
}
}
}
}
}
impl<
D: Decoder,
T0: Decodable<D>,
T1: Decodable<D>,
T2: Decodable<D>,
T3: Decodable<D>
> Decodable<D> for (T0, T1, T2, T3) {
fn decode(d: &D) -> (T0, T1, T2, T3) {
do d.read_tup(4) {
(
d.read_tup_elt(0, || Decodable::decode(d)),
d.read_tup_elt(1, || Decodable::decode(d)),
d.read_tup_elt(2, || Decodable::decode(d)),
d.read_tup_elt(3, || Decodable::decode(d))
)
}
}
}
impl<
S: Encoder,
T0: Encodable<S>,
T1: Encodable<S>,
T2: Encodable<S>,
T3: Encodable<S>,
T4: Encodable<S>
> Encodable<S> for (T0, T1, T2, T3, T4) {
fn encode(&self, s: &S) {
match *self {
(ref t0, ref t1, ref t2, ref t3, ref t4) => {
do s.emit_tup(5) {
s.emit_tup_elt(0, || t0.encode(s));
s.emit_tup_elt(1, || t1.encode(s));
s.emit_tup_elt(2, || t2.encode(s));
s.emit_tup_elt(3, || t3.encode(s));
s.emit_tup_elt(4, || t4.encode(s));
}
}
}
}
}
impl<
D: Decoder,
T0: Decodable<D>,
T1: Decodable<D>,
T2: Decodable<D>,
T3: Decodable<D>,
T4: Decodable<D>
> Decodable<D> for (T0, T1, T2, T3, T4) {
fn decode(d: &D)
-> (T0, T1, T2, T3, T4) {
do d.read_tup(5) {
(
d.read_tup_elt(0, || Decodable::decode(d)),
d.read_tup_elt(1, || Decodable::decode(d)),
d.read_tup_elt(2, || Decodable::decode(d)),
d.read_tup_elt(3, || Decodable::decode(d)),
d.read_tup_elt(4, || Decodable::decode(d))
)
}
}
}
// ___________________________________________________________________________
// Helper routines
//
// In some cases, these should eventually be coded as traits.
pub trait EncoderHelpers {
fn emit_from_vec<T>(&self, v: &[T], f: &fn(v: &T));
}
impl<S:Encoder> EncoderHelpers for S {
fn emit_from_vec<T>(&self, v: &[T], f: &fn(v: &T)) {
do self.emit_owned_vec(v.len()) {
for v.eachi |i, e| {
do self.emit_vec_elt(i) {
f(e)
}
}
}
}
}
pub trait DecoderHelpers {
fn read_to_vec<T>(&self, f: &fn() -> T) -> ~[T];
}
impl<D:Decoder> DecoderHelpers for D {
fn read_to_vec<T>(&self, f: &fn() -> T) -> ~[T] {
do self.read_owned_vec |len| {
do vec::from_fn(len) |i| {
self.read_vec_elt(i, || f())
}
}
}
}